JPS5819043A - Branching construction for optical submarine cable - Google Patents

Abstract

PURPOSE:To branch optical fiber core wires, by providing a separation box branching an optical submarine cable and connecting feeders, and an earth box connecting the feeder to a grounding point at submarine via an external housing. CONSTITUTION:A separation box 1 and an earth box 2 are connected with an optical submarine cable 3 of comparatively short length and a feeder 7 of optical submarine cables 4 and 3 connected to the earth box 2 is connected to an external housing of the earth box 2. The separation box 1 splits four optical fiber core wires 6 from the cable 3 at each two cores and connected to an optical submarine cable 5. The feeder 7 of the cables 3 and 5 is connected to each other.

Description

[Detailed description of the invention] The present invention relates to a branching structure for an optical submarine cable.

Conventionally, for example, submarine cables using coaxial cables simply connect two stations on land with one submarine cable, and do not have a branch structure. A vertical transmission path is constructed by dividing one coaxial cable into a high frequency band and a low frequency band and performing bidirectional transmission. For this reason, transmission capacity is determined by the highest frequency of the system, and worldwide, the maximum capacity is several thousand telephone lines below 50 MHz. In this way, long-distance submarine coaxial cables are single-core (one pair of inner and outer conductors).
Therefore, it is structurally difficult to branch.

Although it is possible to branch electrically, techniques such as band division and aggregation are complicated, and it is difficult to install the necessary equipment on the ocean floor, so a branch structure is not adopted.

In recent years, as optical submarine cables have come into use, transmission capacity has increased dramatically. Optical submarine cables generally accommodate multiple optical fibers, so if some of them can be branched out, system flexibility can be obtained, and transmission lines with the necessary capacity can be economically realized in the necessary sections. can. However, in order to regenerate and repeat the attenuation of optical signals transmitted through optical fibers, it is necessary to supply power from a land station to an optical repeater inserted in the middle of an optical submarine cable. Power is supplied to the optical repeaters from a land station by connecting all the power supply parts of the optical repeaters in series to a feed line interposed in the optical submarine cable.

Earth or seawater is usually used for the power return path. The above-mentioned power supply line does not necessarily have to be an independent conductor, but may be, for example, a tensile wire interposed in the cable to protect the optical fiber from mechanical tension, or a tensile wire to protect the optical fiber from water pressure. It can be used by electrically insulating water pressure pipes, etc.

The present invention utilizes the multi-pair structure of the optical submarine cable and the feeder line as described above to provide a branching structure of the optical submarine cable that enables the branching of eight optical fibers on the seabed and the corresponding feed. There are (8) in providing.

The branching structure of the present invention includes a separation box that is inserted in the middle of an optical submarine cable, branches the optical submarine cable, and connects a power feeder line interposed in each optical submarine cable, and The present invention is characterized by comprising an earth box that is inserted in the middle of the optical submarine group and connects the power supply line interposed in the cable to the submarine ground via an external casing.

Next, one embodiment of the present invention will be explained in detail with reference to the drawings.

FIG. 1 is a conceptual diagram showing one embodiment of the present invention. That is, the separation box 1 and the earth box 2 are connected by a relatively short optical submarine cable 8, and the feeder lines 7 of the optical submarine cables 4 and 8 connected to the earth box 2 are connected to the external casing of the earth box 2. The optical submarine cables 8 and 4 are continuous and integrally formed cables,
The structure may be such that the power supply line 7 is connected to the external casing of the earth box 2. In either case, the supply (4) 1JL line 7 and the connecting conductor with the external case are insulated and protected from seawater inside the earth box 2, and are exposed to seawater through the outer surface of the external case of the earth box 2. Must be grounded. The separation box 1 divides the four optical fiber core wires 6 from the optical submarine cable 3 into two each, and connects each fiber to the optical submarine group 5. Also,
This is a structure in which power feed lines 7 of optical submarine cables 5 and 8 are interconnected.

FIG. 2 shows another embodiment of the invention. In case B, the separation box 1 and the earth box 2 of the embodiment shown in FIG. 1 are formed into one body to constitute a separation box 1'. The separation box 1' branches and connects the optical fiber core wires 6, and connects the feed lines of each cable to the external housing by commonly connecting the wires 7. In this case, it is necessary that the external casing of the separation box 1' is made of metal, and that the metal parts are free from corrosion.
Appropriate anti-corrosion structure and coating are required. The contact with the seawater is achieved through the outer surface of the outer casing or a ground plate (not shown) connected to the outside of the outer casing. FIG. 8 shows an embodiment in which an optical relay 2 9 is built into a similar separation box 1''.

In this case, since it also serves as an optical submarine repeater, there is no need for an independent separate box, and the number of cases inserted into the cable is reduced, which is economical and also advantageous in terms of installation.

FIG. 4 is an external view of the embodiment shown in FIG. 1, which has a structure in which the separation box 1 and the earth box 2 are connected by an optical submarine kelp 8.

FIG. 5 is an external view of the embodiment shown in FIG. 2.

FIG. 6 is a diagram showing an example of a system configuration to which the present invention is applied, and FIG. 7 is an example of another system configuration. The system shown in FIG. 6 is land station A.

This is an example in which optical submarine cable transmission lines are provided between 8 and A and 0, respectively, and the optical fiber core wires are branched by the separation run box S1 of the present invention, and the optical repeater R8
Power is supplied to ~R in series from land station A using a power feed line in the cable, and is grounded to underwater ground E through the external casing of separation box S1. Optical relay F-
Power is supplied to R4 to R0 from land station B and grounded to underwater ground E1, and power to optical relays R7 to R0 is similarly supplied from land station C. Since the underwater grounding E1 has isometrically low resistance, power can be supplied to each of the above-mentioned sections independently. In the system shown in FIG. 7, from the land station A to the B station, the feed 11 in the optical submarine couple is connected in series to consistently flow a current I, and is grounded at the B station. In addition, the power supply current Itit from station 0 is grounded to the underwater ground E by the separation box S, and the power supply current I from the D station is grounded to the underwater ground E by the separation box S.

ground to. In this case, the feeder line interposed in the inter-office cable between FiA station B is connected to the separation box St, St
is not connected to the external casing. Therefore, power can be supplied to each section independently.

FIG. 8 is a detailed connection diagram of the system shown in FIG. 1. That is, between land stations A and B there are two optical fiber cores a! A vertical optical transmission path is formed by the FB, and pressure optical relays 5Rt to R0 and a separation box S1 are inserted in the middle. Also, station A and 0
Similarly, a vertical optical transmission path is formed between the station and the station using two optical fiber core wires FB.

And Separation 4? In Tux S1, the optical submarine cable feed '[JpL' is commonly connected and grounded to the underwater ground E1 via the casing. Power is supplied from land station A,
Connect the optical repeaters in series from B and C,
The flight will be carried out on a return route from underwater touchdown E.

As described above, in the present invention, the optical fiber core wire is branched by the separation box, and the feeder line is grounded underwater by the separation box itself or a separately provided earth box, so the optical submarine cable is branched as appropriate. Thus, it is possible to realize a transmission path of arbitrary capacity between eight or more land stations. It enables efficient use of the ultra-multiplex transmission capacity, which is a feature of optical submarine cables, and provides flexibility in power supply methods and system configurations. Furthermore, since power can be supplied independently from each land station, even if one power supply route becomes impaired, other circuits will not be affected.

Further, by dividing the power supply, there is an advantage that the power supply voltage can be lowered. Furthermore, in the event of a fault occurring in the cable itself, by isolating the fault up to the i4 bottom ground, the fault section can be easily isolated, and the fault point within that section can be located in a short time and with high visibility. Various effects can be expected, such as contributing to the As mentioned above, in addition to improving the flexibility and reliability of the system,
It produces many side effects.

[Brief explanation of the drawing]

Fig. 1 is a conceptual diagram showing one embodiment of the present invention, Fig. 2 is a conceptual diagram showing another embodiment of the invention, Fig. 8 is a diagram showing an embodiment incorporating an optical repeater, and Fig. 4. 1 is an external view of the embodiment shown in FIG. 1, FIG. 5 is an external view of the embodiment shown in FIGS.
FIG. 7 is a diagram showing an example of another system configuration to which the present invention is applied, and FIG. 8 is a diagram showing details of the system shown in FIG. 6.
This is the fourth diagram. In the figure, 1. 1', 1"... Separation box, 2... Earth box, 8-5... Optical submarine cable, 6... Optical fiber core wire, 7... Power supply line, 8... Undersea grounding, 9... Optical repeater, A, B, C,
D...Land station, R7-R9...Hikari 11ii, S,
~S,... Separation box. FB...optical fiber, PL...supply gL record. Agent: Patent Attorney Toshimune Sumita -232- Figure 5

Claims (1)

[Scope of Claims] (1) A separation box that is inserted in the middle of an optical submarine cable, branches the optical submarine cable, and connects the feeder line interposed in each optical submarine cable, and the separation box A branching structure for an optical submarine cable, comprising: an earth box that is inserted into the optical submarine cable near the box and connects a power supply line interposed in the cable to a submarine ground via an external casing. (2. The branching structure of the optical submarine cable described in claim 1, characterized in that the censure box and the earth box are integrally formed. (3) Claim 1) The branching structure of an optical submarine bottom pull according to item 1 or item 2, characterized in that an optical repeater is built in the separation box.